Choosing an open source PostgreSQL operator for Kubernetes used to be a question about features and community size. In 2026, it has become a question about licensing posture, image distribution, and whether the project you pick today will still be operationally open in three years. This is part 1 of a 3-part series on running … Continued

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When the future of pgBackRest suddenly became uncertain, the PostgreSQL ecosystem reacted quickly. At Percona, we believed the most important question was not: what replaces it? but: how do we ensure pgBackRest remains healthy, sustainable, and open for everyone? That distinction matters. pgBackRest is critical infrastructure used by enterprises around the world to protect some … Continued

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This is part of our series going through OSTEP book chapters. The OSTEP textbook is freely available at Remzi's website if you like to follow along.

This chapter extends the CPU virtualization playbook to memory. It's the same recipe: let the program run directly on the hardware, but interpose at carefully chosen points so the OS retains control. For memory, this happens at every memory access. Every load, store, and instruction fetch gets translated by hardware from a virtual to a physical address.

The mechanism here is called dynamic relocation, dating to the late 1950s. The base register holds the physical address where the process's address space starts, the bounds register holds its size. On every memory reference the hardware adds base and checks against bounds. If the address is out of range, the CPU raises an exception, and the OS kills the offender.

This takes collaboration between hardware and the OS. Hardware provides privileged mode, the base/bounds registers, translation circuitry, exception generation, and privileged instructions to update the registers. The OS provides memory allocation (a free list, in the simplest case), base/bounds management across context switches, and the exception handlers themselves.

Because there is only one base/bounds pair per CPU, the OS must save and restore them in the process control block(PCB). This means that while a process is descheduled, the OS can freely move its address space and then update the saved base. The process wakes up oblivious to this, hence the name dynamic relocation.

The chapter is transparent about what base-and-bounds gets wrong. The relocated process gets a fixed-size slot, but its stack and heap occupy only a small fraction of it, which means that the space in between causes internal fragmentation. With every process getting the same fat slot regardless of actual footprint, the physical memory fills up quickly. The segmentation discussion, coming next chapter, aims to fix this.

I listened to this book as an audiobook through the Libby app, which basically brings your public library to your phone.

The Thinking Machine is about Jensen Huang and the rise of Nvidia from graphics chips to AI dominance.  The author, Stephen Witt, is a long-form tech journalist. His writing is nice and clear. But it does not have a distinctive voice. I kept thinking of Michael Lewis, whose books have more narrative personality and rhythm.

The book is written for a lay audience. Technical ideas are explained in simplified terms. Much of these were already familiar to me, and I had also lived through Nvidia going from graphics cards to AI chips. (I wish I had bought more stock.)

I was hoping to learn more about Jensen, his philosophy, habits, inner life, management style. There is not much of that in the book. I think that absence is telling. Jensen comes across as a very private person, and almost monastic about work. There does not seem to be a boundary there: he has become one with the work and the company.

The early years were the most interesting to me: young Jensen, finishing college, excelling at AMD, getting married, and the fragile early days of Nvidia. Nvidia was founded at a Denny's in San Jose when Jensen was 30 years old. By 1996 the company was a month from bankruptcy. The first chip had been an architectural dead end, the Sega contract had collapsed, and half the staff was gone. They were betting everything on a single new chip  designed in nine months and verified almost entirely through emulation since there was no time for the usual hardware prototype cycle. No spoilers: it worked, they survived. I think Jensen's resilience, obsession, and inability to let anything go must have been forged in those years. I suspect Jensen's resilience, obsession, and inability to let anything go were forged in those years. And it is hard to ignore that the company that nearly died for lack of simulation went on to make simulation (CUDA, PhysX, Isaac, DRIVE, Omniverse) one of its defining strategic bets.

One recurring theme in the book is what it calls "strategic rage". Jensen publicly criticizes (no berates and yells at) people during meetings. The idea here is that the correction becomes educational for everyone in the room. So Jensen is characterized as giving a harsh lesson and making this a teaching point for others. (Then again, the book also says he shouted at his top-price culinary oven after messing up a recipe. What was strategic about that one?)

So is he an asshole?

I gotta accept, I would feel that way if I were on the receiving end of the yelling (or even in the same room during the yelling). But the picture in the book is more complicated. Jensen does not seem to be driven by cruelty or ego. He doesn't fire people, and tries to educate/elevate them after hiring.

To psychoanalyze the guy from a far, I think he has become one with the work and the mission. He is obsessive, controlling, and emotionally fused with the mission. When the work fails, he reacts viscerally. Apparently even kitchen appliances are not spared.

I found myself oddly sympathetic with Jensen. Maybe because competence is increasingly rare these days. After dealing with enough half-hearted work, incompetent contractors, and people who do not care, I began to deeply value competence. 

Here is a strange example: someone pickpocketed my wallet near the Trevi Fountain in Rome. After the initial shock and the credit-card cancellations, I found myself thinking: this person was unbelievably good at their job. I felt nothing, no bump, no distraction, nothing... The wallet disappeared from the deep front pocket of my jeans like a magic trick. Respect! I remember thinking: if only I were that good/competent at my own work.

That is the feeling Jensen inspires for me. Competence at terrifying scale. Yes, he gets angry and yells in the face of incompetence. But he cares deeply, and he is the hardest worker in the company. I would still work for him. I would want him leading my army.

That temper made the rounds online recently. Jensen went on Dwarkesh Patel's podcast in April, and the middle section turned into a long argument about exporting GPUs to China. Dwarkesh played devil's advocate, channeling Dario Amodei's earlier framing: more compute to China means more risk, especially if a model like Anthropic's Mythos lands there first.

Jensen answered the question. Then he answered it again. Then he answered it a third time from yet another angle. China already has the compute. The 7nm gap is offset by energy abundance and parallelism. Restricting exports just builds Huawei's ecosystem faster (this is exactly what happened when the U.S. ceded telecoms). He made the marginal-sales argument, the CUDA stickiness argument. He laid out a structured case. Eventually, after the same question came back yet again in the same wording, he pushed back hard: "you're not talking to somebody who woke up a loser". The news and people on Reddit seized on this as Jensen losing his composure.

But Dwarkesh dropped the ball there, not Jensen! There might be real holes to pick at in Jensen's case and maybe a case for a competent pushback to move the conversation forward. Instead Dwarkesh kept re-asking the same question in the same wording, leaning on Dario's framing like a script. That was a total failure. A competent interviewer does the homework, identifies the load-bearing claim, and presses on the one place it cracks. Be hard on Jensen, by all means, but bring something. Do not just run the same query against the same response expecting different output. Jensen showed competence in that interview, and he couldn't forgive the total incompetence on Dwarskesh's side. By the way, I was also shouting at Dwarkesh when he kept repeating the same question without listening to Jensen's answers.

Ok, enough said, let's move on...

The most important thing the book communicates is that Nvidia's success was not luck. Jensen saw the importance of parallel computation early and he bet on it more than a decade before the bet paid off. CUDA launched in 2006 as a way to make the GPU programmable for general work, not just graphics. The thesis was that someday someone would need massive parallelism for something other than rendering polygons. Until then Nvidia kept building the toolchain, the libraries, the developer ecosystem, and quietly absorbed the cost. Scientific computing and data analytics were the early adopters, but the market was small and the R&D was very expensive. Wall Street hated CUDA. Activist investors pushed Jensen to kill it. The stock went down. By the late 2000s, the thesis looked like a lost bet.

Then AlexNet happened in 2012, and every machine learning researcher in the world became customers. AI walked into the building Jensen had been constructing for a decade. By the time competitors understood the opportunity, Nvidia had a software moat that hardware alone could not catch.

This part impressed me most: Jensen's conviction on the thesis sustained over decades. He was willing to be misunderstood for more than a decade, because he believed in that thesis. Dwarkesh... bruh, please... fight in your own weight class.

> Two groups of friends try to book seats ranges 5–8 and 7–9 in the same row, for the same show, at the same time. One of them must fail. An ACID database can help enforce this rule. The question is: how much collateral damage does your concurrency control cause for everyone else?

In modern development, we tend to put the business logic in the application first. Still, enforcing business invariants in the database with integrity constraints may provide better performance when it avoids the need for the serializable isolation level required when the invariant concerns multiple rows. This is the case for foreign keys and unique constraints, and here is another example.

In a previous post of this series, we saw how Oracle SQL Assertions can work around the limitations of Oracle's Snapshot Isolation (improperly called SERIALIZABLE). We explored the rule: "each shift must always have at least one doctor on call", which is an example of a table-level invariant — a constraint that requires at least one row satisfying a given condition to exist at all times. This goes beyond what traditional row-pair constraints can express.

Most databases provide only the unique constraint, which enforces that no two rows share the same value(s) for a set of columns. PostgreSQL extends this with exclusion constraints, which generalize the concept: rather than just preventing duplicate values, they prevent any two rows from satisfying a specified pairwise condition — for example, preventing two time ranges from overlapping.

Here is an example of such a business rule: we manage a movie theater where customers can book consecutive seats in a row for themselves and their friends.

Oracle Database: assertion

The booking table identifies the seats for a session (SHOWING_ID) by the row (ROW_NUMBER) and the seat number range (SEAT_START, SEAT_END):

Name           Null?       Type
______________ ___________ ______________________________
BOOKING_ID     NOT NULL    RAW(16 BYTE)
SHOWING_ID     NOT NULL    RAW(16 BYTE)
ROW_NUMBER     NOT NULL    NUMBER(38)
SEAT_START     NOT NULL    NUMBER(38)
SEAT_END       NOT NULL    NUMBER(38)
CUSTOMER_ID    NOT NULL    RAW(16 BYTE)
CREATED_AT                 TIMESTAMP(6) WITH TIME ZONE

Typically, customers query look at the free seats in their preferred row, and book an available range that is free and can fit the number of seats they need. A serializable transaction would be needed to be sure that what is read is not booked by another in the meantime, but Oracle's SERIALIZABLE isolation level does not provide true serializability — it implements Snapshot Isolation, which permits write skew anomalies and doesn't prevent a new booking from being committed that overlaps what was read. With SQL assertions, you can take another approach: create an integrity constraint that raises an error in case of overlap:

CREATE ASSERTION no_overlapping_seats
CHECK (
    NOT EXISTS (
        SELECT 1 
        FROM bookings b1
        WHERE EXISTS (
            SELECT 1 
            FROM bookings b2
            WHERE b1.showing_id = b2.showing_id
              AND b1.row_number = b2.row_number
              AND b1.booking_id <> b2.booking_id
              -- Intersection logic:
              AND b1.seat_start < b2.seat_end
              AND b2.seat_start < b1.seat_end
        )
    )
);

The rule says that there cannot exist two bookings within the same show for the same row with overlapping start/end seat ranges.

The assertion uses the existential negation form (NOT EXISTS). The universal quantifier version, which may be easier to understand, says that for any two different bookings on the same show and row, the seat ranges must not overlap (one ends before the other starts):

∀ b1, b2 ∈ Bookings : (
    b1.show = b2.show ∧ b1.row = b2.row ∧ b1.id ≠ b2.id
) ⇒ (
    b1.start ≥ b2.end ∨ b2.start ≥ b1.end
)

This is equivalent, by De Morgan's law (x ∨ y ≡ ¬(¬x ∧ ¬y)), to saying it cannot be the case that both ranges extend into each other:

∀ b1, b2 ∈ Bookings : (
    b1.show = b2.show ∧ b1.row = b2.row ∧ b1.id ≠ b2.id
) ⇒ ¬ (
    b1.start < b2.end ∧ b2.start < b1.end
)

Now, applying quantifier duality (∀x : P ⇒ ¬Q ≡ ¬∃x : P ∧ Q), it is easy to understand the existential negation version that maps directly to the NOT EXISTS assertion:

¬∃ b1, b2 ∈ Bookings : (
    b1.show = b2.show ∧ b1.row = b2.row ∧ b1.id ≠ b2.id
  ∧
    b1.start < b2.end ∧ b2.start < b1.end
)

With this, any concurrent inserts for the same show and same row will wait, and after the wait, the seat ranges will be checked and ORA-08601: SQL assertion (NO_OVERLAPPING_SEATS) violated will be raised if they overlap. This works but is not ideal because it will wait even if the seats do not overlap. However, two non-overlapping bookings in the same show and row will still block before being accepted becaise assertions lock on exact column values (here, the combination of showing_id and row_number), not on ranges within those values.

It is possible to get better concurrency for that rule with PostgreSQL exclusion constraints, but first, let's check with serializable as PostgreSQL supports true Serializable Snapshot Isolation (SSI).

PostgreSQL: serializable

To get a fully reproducible example, I create all necessary tables for the theater's screens, movies, showings, and bookings:

CREATE TABLE screens (
    screen_id UUID PRIMARY KEY,
    name TEXT NOT NULL,
    rows INT NOT NULL, 
    seats_per_row INT NOT NULL 
);

INSERT INTO screens (screen_id, name, rows, seats_per_row) VALUES
('a1b2c3d4-0001-4000-8000-000000000001', 'Alpha Station', 25, 36),
('a1b2c3d4-0001-4000-8000-000000000002', 'Big Market', 18, 28),
('a1b2c3d4-0001-4000-8000-000000000003', 'Mül Paradise', 12, 20),
('a1b2c3d4-0001-4000-8000-000000000004', 'Kirian Corridor', 15, 24);

CREATE TABLE movies (
    movie_id UUID PRIMARY KEY DEFAULT gen_random_uuid(),
    title TEXT NOT NULL,
    year INT NOT NULL,
    duration_minutes INT NOT NULL,
    director TEXT NOT NULL DEFAULT 'Luc Besson'
);

INSERT INTO movies (movie_id, title, year, duration_minutes) VALUES
('b0b0b0b0-0001-4000-8000-000000000001', 'Subway', 1985, 104),
('b0b0b0b0-0001-4000-8000-000000000002', 'The Big Blue', 1988, 168),
('b0b0b0b0-0001-4000-8000-000000000003', 'Nikita', 1990, 117),
('b0b0b0b0-0001-4000-8000-000000000004', 'Léon: The Professional', 1994, 110),
('b0b0b0b0-0001-4000-8000-000000000005', 'The Fifth Element', 1997, 126),
('b0b0b0b0-0001-4000-8000-000000000006', 'Angel-A', 2005, 90),
('b0b0b0b0-0001-4000-8000-000000000007', 'Lucy', 2014, 89),
('b0b0b0b0-0001-4000-8000-000000000008', 'Valerian and the City of a Thousand Planets', 2017, 137),
('b0b0b0b0-0001-4000-8000-000000000009', 'Anna', 2019, 119),
('b0b0b0b0-0001-4000-8000-000000000010', 'Dogman', 2023, 114);

CREATE TABLE showings (
    showing_id UUID PRIMARY KEY DEFAULT gen_random_uuid(),
    movie_id UUID NOT NULL,
    screen_id UUID NOT NULL,
    start_time TIMESTAMPTZ NOT NULL
);

INSERT INTO showings (showing_id, movie_id, screen_id, start_time) VALUES
-- Friday
('c0c0c0c0-0001-4000-8000-000000000001', 'b0b0b0b0-0001-4000-8000-000000000005', 'a1b2c3d4-0001-4000-8000-000000000001', '2025-01-24 19:00:00+01'),
('c0c0c0c0-0001-4000-8000-000000000002', 'b0b0b0b0-0001-4000-8000-000000000004', 'a1b2c3d4-0001-4000-8000-000000000003', '2025-01-24 20:00:00+01'),
('c0c0c0c0-0001-4000-8000-000000000003', 'b0b0b0b0-0001-4000-8000-000000000008', 'a1b2c3d4-0001-4000-8000-000000000002', '2025-01-24 21:00:00+01'),
('c0c0c0c0-0001-4000-8000-000000000004', 'b0b0b0b0-0001-4000-8000-000000000007', 'a1b2c3d4-0001-4000-8000-000000000004', '2025-01-24 22:00:00+01')
;

CREATE TABLE bookings (
    booking_id UUID PRIMARY KEY DEFAULT gen_random_uuid(),
    showing_id UUID NOT NULL REFERENCES showings(showing_id),
    row_number INT NOT NULL,
    seat_range INT4RANGE NOT NULL,  -- e.g., [5,9) means seats 5,6,7,8
    customer_id UUID NOT NULL,
    created_at TIMESTAMPTZ DEFAULT now()
);

INSERT INTO bookings (booking_id, showing_id, row_number, seat_range, customer_id) VALUES
('d0d0d0d0-0001-4000-8000-000000000001', 'c0c0c0c0-0001-4000-8000-000000000001', 12, '[15,19)'::int4range, 'e0e0e0e0-0001-4000-8000-000000000001'),
('d0d0d0d0-0001-4000-8000-000000000002', 'c0c0c0c0-0001-4000-8000-000000000001', 12, '[19,21)'::int4range, 'e0e0e0e0-0001-4000-8000-000000000002'),
('d0d0d0d0-0001-4000-8000-000000000003', 'c0c0c0c0-0001-4000-8000-000000000001', 13, '[10,16)'::int4range, 'e0e0e0e0-0001-4000-8000-000000000003'),
('d0d0d0d0-0001-4000-8000-000000000004', 'c0c0c0c0-0001-4000-8000-000000000001', 14, '[1,5)'::int4range, 'e0e0e0e0-0001-4000-8000-000000000004'),
('d0d0d0d0-0001-4000-8000-000000000005', 'c0c0c0c0-0001-4000-8000-000000000001', 14, '[30,36)'::int4range, 'e0e0e0e0-0001-4000-8000-000000000005');

INSERT INTO bookings (
 showing_id,
 row_number,
 seat_range,
 customer_id
) VALUES (
 'c0c0c0c0-0001-4000-8000-000000000002',
  12,
  '[ 1, 3)'::int4range,
  gen_random_uuid()
)
;

PostgreSQL has a built-in range datatype. A range like [5,8) represents a half-open interval — it includes 5, 6, and 7 but not 8. The [ means inclusive, ) means exclusive. This is the standard representation for discrete ranges in PostgreSQL, and it means I can store the seat range in a single column instead of two columns like in Oracle Database. PostgreSQL also provides operators on ranges, notably && (overlaps) which returns true when two ranges share any points in common.

Typically a service that checks the available seats for a show and books a range of seats will use a serializable transaction:

BEGIN ISOLATION LEVEL SERIALIZABLE;

-- query the show's booked seats
SELECT row_number,seat_range,now() 
 FROM bookings 
 WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002';

-- find a range available and book it 
INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  
 VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[ 5, 8)'::int4range, gen_random_uuid())
 RETURNING customer_id, booking_id, created_at;

-- wait time added to hold the transaction open long enough for others 
-- to start and attempt to commit concurrently
select pg_sleep(10); 

-- commit the transaction or fail if not serializable
COMMIT;

For this show and row, only seats in range [ 1, 3) are currently booked. I run my transactions in parallel for ranges [ 5, 8), [25,28), [ 7,10) so I expect only one of [ 5, 8) and [ 7,10) to succeed, in addition to [ 5, 8) which do not overlap with anyone:

\! psql -ec '\timing on' -c "begin isolation level serializable; SELECT row_number,seat_range,now() FROM bookings WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002'; INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[ 5, 8)'::int4range, gen_random_uuid()) returning customer_id, booking_id, created_at; select pg_sleep(10) ; commit;"   & sleep 1

\! psql -ec '\timing on' -c "begin isolation level serializable; SELECT row_number,seat_range,now() FROM bookings WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002'; INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[25,28)'::int4range, gen_random_uuid()) returning customer_id, booking_id, created_at; select pg_sleep(10) ; commit;"   & sleep 1

\! psql -ec '\timing on' -c "begin isolation level serializable; SELECT row_number,seat_range,now() FROM bookings WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002'; INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[ 7,10)'::int4range, gen_random_uuid()) returning customer_id, booking_id, created_at; select pg_sleep(10) ; commit;"   & sleep 1

Note: the \! commands launch background shell processes with &, staggered by 1-second sleeps, to simulate concurrent users hitting the database at nearly the same time.

As it was first, [5,8) succeeded:

postgres=# SELECT row_number,seat_range,created_at
 FROM bookings
 WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002' 
 ORDER BY created_at
;
 row_number | seat_range |          created_at
------------+------------+-------------------------------
         12 | [1,3)      | 2026-05-14 10:12:58.322202+00
         12 | [5,8)      | 2026-05-14 10:15:26.063663+00
(2 rows)

Both [25,28) and [ 7,10) have waited for the first one to commit and have failed, not because of overlap, as both viewed the seats free from their query (the first transaction wasn't committed yet), but because of serialization:

ERROR:  could not serialize access due to read/write dependencies among transactions
DETAIL:  Reason code: Canceled on identification as a pivot, during commit attempt.
HINT:  The transaction might succeed if retried.
Time: 10004.080 ms (00:10.004)

Serializable Snapshot Isolation (SSI) uses predicate locks to track what each transaction has read. Here, all three transactions read the same set of rows for the showing — SSI records a predicate lock on the showing_id filter condition. When the first transaction commits its insert, the other transactions have a read-write dependency: they read a state that no longer exists (the showing now has a new booking). SSI detects this (a "pivot" in the dependency graph) and aborts the transactions that cannot be guaranteed to produce a serializable outcome. The granularity of SSI predicate locks means the entire showing's bookings are effectively locked — not just the specific seat range. This is why [25,28), which doesn't overlap with anything, still fails.

For better concurrency, we need to lower the isolation level and enforce the overlap prevention as an in-database integrity constraint. In short, we enforce the logic using the C instead of I from ACID properties.

PostgreSQL: EXCLUDE constraint

PostgreSQL's exclusion constraints generalize unique constraints: instead of checking only equality between rows, they can check any combination of operators. The constraint is backed by an index (typically GiST) that efficiently finds conflicting rows at insert or update time. The key insight is that the constraint acts as a materialized conflict check — it evaluates against the current committed state of the table at the moment of the insert, independent of what the transaction previously read. This is why we can safely drop down to Read Committed isolation.

Exclusion constraints require a GiST index on the range for the overlap operator &&. Since I also have equality operators = on non-range columns ("showing_id", "row_number"), I need to enable the btree_gist extension — it's shipped with PostgreSQL and adds GiST operator classes for scalar types like UUID and integer, allowing them to be mixed with range types in a single GiST index. Then I can declare the exclusion constraint that will raise an error on seat range overlap for the same show and row:

-- Need the btree_gist extension for mixing = and && operators
CREATE EXTENSION IF NOT EXISTS btree_gist;

ALTER TABLE bookings ADD
    CONSTRAINT no_overlapping_seats
        EXCLUDE USING GIST (
            showing_id WITH =,
            row_number WITH =,
            seat_range WITH &&      -- && = "overlaps" operator
        )
;

The EXCLUDE USING GIST declaration reads: "no two rows may exist where showing_id equals, row_number equals, AND seat_range overlaps." The GiST index makes this check efficient — PostgreSQL doesn't scan the whole table, it uses the index to find only potentially conflicting rows.

If you forget to create the btree_gist extension, you'll encounter the following error:

ERROR:  data type uuid has no default operator class for access method "gist"  
HINT:  You must specify an operator class for the index or define a default operator class for the data type.  

The reason is that GiST indexes natively support only geometric and range types (with operators like &&, @>, <<). Scalar types like uuid, integer, or text have no built-in GiST operator class — they normally live in B-tree indexes. The btree_gist extension adds GiST operator classes for these scalar types, enabling them to participate in exclusion constraints alongside range operators. The error is misleading because it doesn't say "you need btree_gist" but says "this is not supported by GiST alone".

Here are some inserts to test it:

-- This should FAIL (overlaps with seats [15,19) in row 12, showing ...0001)
INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)
VALUES ('c0c0c0c0-0001-4000-8000-000000000001', 12, '[17,22)'::int4range, gen_random_uuid());

-- This should SUCCEED (adjacent, seats [21,25) in row 12)
INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)
VALUES ('c0c0c0c0-0001-4000-8000-000000000001', 12, '[21,25)'::int4range, gen_random_uuid());

-- This should SUCCEED (same row 12 but different showing)
INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)
VALUES ('c0c0c0c0-0001-4000-8000-000000000004', 12, '[15,19)'::int4range, gen_random_uuid());

You can validate that overlapping ranges of seats are not permitted for the same row in the same show. However, this doesn't show the concurrency advantages of it like a parallel testing.

I delete the booking for [5,8) that succeeded before, so that I can run my parallel test again:

DELETE FROM bookings 
 WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002' 
 AND row_number=12 AND seat_range='[ 5, 8)'::int4range
;

Now, I can run my transactions in Read Committed isolation level because the constraint prevents the overlap, regardless of what was read initially. The exclusion constraint checks for conflicts against committed data at insert time — even if the transaction's earlier SELECT didn't see the conflicting row:

\! psql -ec '\timing on' -c "begin isolation level read committed; SELECT row_number,seat_range,now() FROM bookings WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002'; INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[ 5, 8)'::int4range, gen_random_uuid()) returning customer_id, booking_id, created_at; select pg_sleep(10) ; commit;"   & sleep 1

\! psql -ec '\timing on' -c "begin isolation level read committed; SELECT row_number,seat_range,now() FROM bookings WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002'; INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[25,28)'::int4range, gen_random_uuid()) returning customer_id, booking_id, created_at; select pg_sleep(10) ; commit;"   & sleep 1

\! psql -ec '\timing on' -c "begin isolation level read committed; SELECT row_number,seat_range,now() FROM bookings WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002'; INSERT INTO bookings (showing_id, row_number, seat_range, customer_id)  VALUES ('c0c0c0c0-0001-4000-8000-000000000002', 12, '[ 7,10)'::int4range, gen_random_uuid()) returning customer_id, booking_id, created_at; select pg_sleep(10) ; commit;"   & sleep 1

Two bookings have succeeded, [5,8) and [25,28), and from the creation time you can see that they didn't have to wait on each other:

postgres=# SELECT row_number,seat_range,created_at
 FROM bookings
 WHERE showing_id='c0c0c0c0-0001-4000-8000-000000000002' 
 ORDER BY created_at
;
 row_number | seat_range |          created_at
------------+------------+-------------------------------
         12 | [1,3)      | 2026-05-14 10:12:58.322202+00
         12 | [5,8)      | 2026-05-14 10:33:25.935444+00
         12 | [25,28)    | 2026-05-14 10:33:26.936793+00
(3 rows)

Only the conflicting range [7,10) waited on the first transaction to commit and then detected the overlap:

ERROR:  conflicting key value violates exclusion constraint "no_overlapping_seats"
DETAIL:  Key (showing_id, row_number, seat_range)=(c0c0c0c0-0001-4000-8000-000000000002, 12, [7,10)) conflicts with existing key (showing_id, row_number, seat_range)=(c0c0c0c0-000
1-4000-8000-000000000002, 12, [5,8)).
Time: 8009.347 ms (00:08.009)

Note that the wait time (~8 seconds instead of ~10) corresponds to the 1-second stagger between the sessions: the third transaction started 2 seconds after the first, so it waited the remaining duration until the first committed. During this wait, PostgreSQL holds a lightweight lock on the potentially conflicting index entry — only transactions inserting an actually overlapping range will block.

Indexes are often used to avoid broader table locks. For example, unique constraints in most databases rely on an index to detect conflicts, and in Oracle, creating an index on a foreign key helps avoid locks for referential integrity checks. PostgreSQL does not need that because it can use share row locks, whereas Oracle implements only exclusive row locks.

The application must interpret this error (SQLSTATE 23P01 — exclusion_violation) as: "those seats are not available" and it should start again the transaction with a fresher seat map. This is similar to how applications handle serialization failures (SQLSTATE 40001) with SSI, but with an important difference: with the exclusion constraint, only actual overlaps trigger the error, so retries are far less frequent.

Summary

The exclusion constraint with GiST index provides the best concurrency: non-conflicting inserts proceed in parallel without waiting or aborting, while true overlaps are precisely detected and rejected. Serializable isolation is more conservative — it must protect against any possible anomaly from the read set, not just overlaps. Oracle assertions are the most expressive (they can enforce arbitrary multi-row predicates) but operate at the granularity of exact value locks, which causes unnecessary blocking when the actual conflict depends on range overlap.

The tradeoff is clear: if your invariant can be expressed as a pairwise exclusion condition with indexable operators, PostgreSQL's EXCLUDE constraint gives you the best of both worlds — declarative integrity with fine-grained concurrency.